WO2022167234A1 - Method for operating a control system of a vehicle with a steering brake function and traction control system - Google Patents

Abstract

The invention relates to a method for operating a control system (300) of a vehicle, which comprises at least the following: A brake device (1), which is controlled by a brake controller (14), with a first brake actuator (50a) for the first drive wheel (98a) and a second brake actuator (50b) for the second drive wheel (98b), a steering brake function with which, by targeted activation of the first brake actuator (50a) and/or of the second brake actuator (50b) of the at least one driven axle (HA), a steering effect on the vehicle can be achieved, a traction control system (ASR) with which an impermissible drive slip at the first drive wheel (98a) and/or at the second drive wheel (98b) of the at least one driven axle (HA) is reduced by intervention in a drive controller (93) of the drive motor (94) and/or by intervention in the brake controller (14) of the brake device (1). The invention makes provision that, if the steering brake function at the at least one driven axle (HA) is active or has been activated, and if then the traction control system (ASR) at the at least one driven axle (HA) is activated, intervention in the brake controller (14) of the brake device (1) is omitted within the scope of the traction control system (ASR).

Description

DESCRIPTION

Method for operating a control system of a vehicle with steering brake function and traction control

The invention relates to a method for operating a control system of a vehicle according to claim 1 and a vehicle, in particular a towing vehicle of a towing vehicle-trailer combination with a control system which is controlled by such a method, according to claim 11 .

Control systems for vehicles with traction control (ASR) are known from the prior art, in which the traction of wheels on a driven axle is regulated to a permissible traction if at least one of the driven wheels has a traction that exceeds the permissible traction. Such a traction control system (ASR) can reduce the speed of driven wheels in a targeted manner by intervening in a brake control of a brake device of the vehicle and an intervention in the drive control of a drive motor of the vehicle in order to reduce impermissibly high traction slip.

In addition, control systems of vehicles with a steering brake function are known, with which a steering effect can be exerted on the vehicle simply by braking the wheels in a targeted manner. Furthermore, differential gears on driven axles, so-called axle differentials, are known, which ensure the equalization of the speeds between the two wheels of the driven axle.

The object of this invention is to provide a method for operating a control system of a vehicle with traction control and with a steering brake function, in which the steering effect caused by the steering brake function is as large as possible. Furthermore, a vehicle with a control system that is operated according to such a method is also to be made available.

This object is achieved according to the invention by the features of claims 1 and 11. Disclosure of Invention

The invention is based on the finding that if the steering brake function is active or has been activated so that the vehicle is cornering, and for this purpose the drive wheel on the inside of the curve is braked but not the drive wheel on the outside of the curve of the driven axle, the (unlocked) differential gear is activated the driven axle accelerates the wheel on the outside of the curve, which then has an increased and, under certain circumstances, impermissibly high drive slip. However, this behavior is desirable solely with the aim of being able to achieve the smallest possible curve radii with the help of the steering brake function. However, the ASR control would then brake the drive wheel on the outside of the curve to the permissible drive slip by intervening in the brake control of the braking device, which in turn would reduce the steering effect and increase the curve radius.

To solve this problem, the invention proposes a method for operating a control system of a vehicle, which has at least the following: a) a drive motor controlled by a drive controller, which drives at least one driven axle with a first drive wheel and a second drive wheel, b) a differential gear between the first drive wheel and the second drive wheel, c) a brake device controlled by a brake controller with a first brake actuator for the first drive wheel and a second brake actuator for the second drive wheel, d) a steering brake function with which, by selectively activating the first brake actuator and/or of the second brake actuator of the at least one driven axle, a steering effect on the vehicle can be achieved, e) traction control, with which impermissible traction slip on the first drive wheel and/or on the second drive wheel of the at least one driven A Axis by e1) an intervention in the drive control of the drive motor, in which the drive power of the drive motor is reduced, and / or by e2) an intervention in the brake control of the braking device, in which a impermissibly traction-slip drive wheel is deliberately braked by the first drive wheel and/or by the second drive wheel, can be traced back to a permissible traction slip, wherein f) if the steering brake function is active or has been activated on the at least one driven axle, and if then and the traction slip control is activated on the at least one driven axle, the intervention in the brake control of the braking device is dispensed with as part of the traction control system.

An “intervention in the brake control” should be understood to mean that the braking device or components of the braking device are activated in order to bring about a braking effect on at least one drive wheel. In an analogous manner, an “intervention in the drive control” should be understood to mean that the drive device or components of the drive device are activated in order to bring about a reduced drive effect on at least one drive wheel

Therefore, the traction control (TCS) of the control system is basically designed so that it can intervene in the drive control of the drive motor and an intervention in the brake control of the braking device in order to limit the traction on the first and/or second drive wheel of the driven axle to a permissible level Reduce drive slip. However, there is no intervention in the braking control of the braking device, i.e. the braking device is not activated if the steering brake function is active or has been activated on the at least one driven axle.

The steering effect initiated or brought about by the steering brake function is then not impaired by braking of the drive wheel on the outside of the curve brought about by means of the traction control system. With the help of the steering brake function, small curve radii can thus be driven, in particular on a roadway or on a surface with a low coefficient of friction. Furthermore, wear-promoting braking interventions of the ASR control can also be avoided, which can also come about because the drive train is tense.

If the steering brake function is active or has been activated on the at least one driven axle, and if then and traction control on the at least a driven axle is activated, but preferably the intervention in the drive control of the drive motor should be carried out within the scope of the traction control system, in which case the drive power of the drive motor is reduced. This advantageously improves the driving stability of the vehicle.

As stated above, the differential gear is designed as an axle differential, which ensures the balancing of the speeds between the two drive wheels of the driven axle.

The differential gear can be designed with a differential lock or without a differential lock or with a switchable differential lock. A (engaged) differential lock creates a rigid drive connection between the first drive wheel and the second drive wheel so that the speeds of the two drive wheels are the same, while with the differential lock switched off or in a differential gear without differential lock there is no rigid drive connection.

The control system, which is operated according to the method according to the invention, should preferably have a differential gear without differential lock or a differential gear with differential lock, in which the differential lock is switched off during operation according to the invention, so that the problems explained above in connection with the invention occur at all.

Advantageous developments of the invention are specified in the dependent claims.

For safety reasons, as part of the traction control system, intervention in the braking control of the braking device can only be dispensed with if the driving speed of the vehicle is less than a specified limit speed (v _< v limit)-

The control system can also further include a) a steering device that can be actuated in particular by a driver of the vehicle, and/or b) an autonomous vehicle controller, and/or c) at least one driver assistance system, by which and/or by which a steering request signal can be generated, with which cornering of the vehicle is to be brought about. The steering request signal can be generated, for example, by the autonomous vehicle control and/or by the driver assistance system if it has been determined that the steering device actuated by the driver of the vehicle has an error or defect. Then the autonomous vehicle control and/or the driver assistance system is (are) used as redundancy for the failed steering device.

The steering brake function can be activated, i.e. set in motion, on the at least one driven axle, in particular in response to the steering request signal. In particular, the steering request signal of the autonomous vehicle control and/or the driver assistance system is used to steer the vehicle if it has been determined that the steering device has an error or defect. The steering request signal is then implemented by means of steering brakes, i.e. with the help of the steering brake function, at least on the at least one driven axle (HA). In addition, of course, the steering braking can also be carried out on a non-driven axle, for example on a steered front axle.

During steering braking, that drive wheel of the first drive wheel and the second drive wheel of the drive axle is preferably braked which represents the drive wheel on the inside of the curve in relation to the cornering represented by the steering request signal. The drive wheel deviating from the drive wheel on the inside of the curve cannot be braked.

In an analogous manner, during steering braking, that wheel of a first non-driven wheel and a second non-driven wheel of a non-driven axle (e.g. a non-driven front axle) is preferably braked which represents the wheel on the inside of the curve in relation to the cornering represented by the steering request signal. The wheel deviating from the wheel on the inside of the curve cannot be braked.

In particular, an electro-pneumatic and electronically controlled brake system (EBS) with a 2-channel pressure control module or with two 1-channel pressure control modules can be used as a braking device, a first 1-channel pressure control module and a second pressure control module, on which at least one driven axis is used, with a first channel of the 2- Channel pressure control module or the first 1-channel pressure control module, a first brake pressure for the first brake actuator and by a second channel of the 2-channel pressure control module or the second 1-channel pressure control module, a second brake pressure for the second brake actuator is individually controllable. Because then the first brake actuator and the second brake actuator are each controlled by a channel of a pressure control module, wheel-specific braking of the first drive wheel and the second drive wheel of the drive axle is possible as part of the steering brake function. Under the above conditions, wheel-specific braking of the first drive wheel and the second drive wheel of the drive axle can then also take place as part of the traction control system.

The traction control system can also be activated automatically if impermissible traction slip has been detected on the first drive wheel and/or on the second drive wheel of the at least one driven axle.

The invention also relates to a vehicle, in particular a towing vehicle of a towing vehicle-trailer combination with a control system which is controlled by a method according to one of the preceding claims.

drawing

An embodiment of the invention is shown in the drawing and explained in more detail in the following description. In the drawing shows

1 shows a schematic circuit diagram of an electro-pneumatic braking device as part of a preferred embodiment of a control system of a towing vehicle of a towing vehicle-trailer combination;

Fig. 2 is a schematic circuit diagram of the control system of the towing vehicle of the towing vehicle-trailer combination;

3 shows a schematic circuit diagram of an electro-mechanical steering device as part of the preferred embodiment of the control system of a towing vehicle of a towing vehicle-trailer combination;

4 shows a flow chart of a preferred embodiment of a method for operating the control system. Description of the embodiment

In Fig. 1, a service brake device 1 is shown schematically as part of a preferred embodiment of a control system 300 of a towing vehicle of a towing vehicle-trailer combination. In the present case, the towing vehicle-trailer combination has a 2-axle semi-trailer, but a drawbar trailer or several drawbar trailers can also be attached to the towing vehicle. The service brake device 1 of the towing vehicle is formed, for example, by an electro-pneumatic friction brake system in the form of an electronically controlled brake system (EBS; Electronic Brake System).

In such an electronically controlled braking system (EBS), there are pressure control modules 16, 36, 38 for each axle or wheel, with integrated inlet valves, outlet valves and backup valves and with pressure sensors for detecting the actual brake pressure and with higher-level control electronics for adjusting the actual brake pressures with the target brake pressures according to the respective braking requirement. The electronically controlled brake system (EBS) of the towing vehicle also includes a brake slip control system (ABS), the ABS control routines of which are preferably integrated in a central brake control unit 14 . Furthermore, traction control (ASR) and an electronic stability program (ESP) are preferably present in the towing vehicle, with the relevant control routines also being implemented in the central brake control unit 14 .

According to the circuit diagram of the electro-pneumatic service brake device 1 of the towing vehicle shown in Fig. 1, there are a foot brake value sensor 2, a front axle pressure reservoir 4 for supplying a front axle pressure circuit or front axle pressure channel and a rear axle pressure reservoir 6 for supplying a rear axle pressure circuit or rear axle -Pressure channel available. The air procurement, air treatment and protection is carried out as required by law by an air treatment module 8, which is not described in detail here.

The rear axle pressure reservoir 6 is connected via pneumatic supply lines 10, 12 to a supply connection of a 2-channel pressure control module 16 for the brake cylinders 50 of the rear axle and to a rear axle foot brake valve 26 of the foot brake value sensor 2. In an analogous manner, the front axle pressure reservoir 4 is connected via pneumatic supply lines 20, 22 Supply connections of two 1-channel pressure control modules 36, 38 each assigned to a brake cylinder 48 of a front wheel and connected to a front-axle foot brake valve 18 of the foot brake transmitter 2. The foot brake value transmitter 2 therefore includes two pneumatically acting foot brake valves 18, 26, which each generate a pneumatic back-up pressure or control pressure at the outputs of the foot brake valves 18, 26 depending on a braking request specified by the driver's foot on a brake pedal. In parallel with this, an electric front axle channel and an electric rear axle channel are combined in an electric channel 28 in foot brake value sensor 2, which, depending on the braking request, transmit an electric brake request signal into an electrical connection, preferably designed as a brake data bus 30, between electric channel 28 of foot brake value sensor 2 and the central electronic brake control unit 14, which can differentiate between the two brake request signals for the front axle and the rear axle, which differ for load reasons, for example. Furthermore, the front-axle foot brake valve 18 and the rear-axle foot brake valve 26 of the foot brake value transmitter 2 are each connected via a pneumatic control line 24, 32 to assigned back-up connections of the 2-channel pressure control module 16 or the 1-channel pressure control module 36, 38 . Furthermore, a respective pneumatic brake line 40, 42 leads from the working pressure connections of the 2-channel pressure control module 16 or the two 1-channel pressure control modules 36, 38 to the wheel-by-wheel brake cylinders 48, 50 of the front axle or the rear axle.

Speed sensors 56 report the current speed of the wheels of the two-axle vehicle to the central brake control unit 14 via electrical signal lines 58. Wear sensors 60 are also preferably provided for each wheel brake, which, depending on the current brake wear, report signals to the central brake control unit 14 via electrical signal lines 62.

Furthermore, a trailer control module 64 is provided, which on the one hand is supplied with compressed air via a supply line 46 from a trailer storage pressure tank 44 on the towing vehicle and on the other hand is controlled pneumatically by back-up pressure by the pneumatic control pressure, for example of the front axle foot brake valve 18 of the foot brake value sensor 2, via a control line 52 . Furthermore, the trailer control module 64 also receives an electrical signal from the central Brake control unit 14 via an electrical control line 54. Finally, the trailer control module 64 is also controlled by a parking brake unit 66, which is not of interest here.

The trailer control module 64 typically contains an inlet solenoid valve and an outlet solenoid valve as well as a backup solenoid valve for pressure control of a relay valve that is also integrated and supplied with compressed air from the trailer compressed air supply 44, in order to generate a control pressure for a Actuate the “brake” coupling head 70. The relay valve modulates the control pressure for the “brake” coupling head 70 from the supply pressure of the trailer pressure reservoir 44 present at its supply connection, depending on the control pressure formed by the solenoid valves. This control pressure for the “brake” coupling head 70 is measured and reported to the central brake control unit 14. If this primary electrical control fails, the integrated back-up valve switches through and the relay valve is controlled by the pneumatic control pressure of the front-axle brake circuit carried in the control line 52 . Finally, the trailer control module 64 loops through the compressed air originating from the trailer compressed air supply 44 under supply pressure to a coupling head “supply” 68 of the towing vehicle. The structure and the functions of such an electro-pneumatic trailer control module 64 are well known and therefore do not need to be explained further here.

The brake application devices of the rear axle are preferably known as combination cylinders, i. H. designed as a combination of an active service brake cylinder 50 and a passive spring brake cylinder. In this context, “active” means that the service brake cylinders 50 apply during ventilation and release when vented, and “passive” means that the spring-loaded brake cylinders apply during ventilation and release during ventilation. In contrast, only active service brake cylinders 48 are provided on the wheels of the front axle.

The electro-pneumatic 2-channel pressure control module 16 designed as a structural unit has two separately controllable pressure control channels, whereby for each pressure control channel on the basis of a supply of air originating from the rear axle compressed air reservoir 6 depending on the brake request signal of the foot brake value sensor 2 a regulated one connected to the respective Working pressure connections pending working pressure for the brake cylinder 50 of the rear axle is generated and measured by means of the integrated pressure sensors in order to adapt or regulate the measured actual brake pressure to the target brake pressure according to the brake request. In an analogous manner, the brake pressure is regulated individually for the two brake cylinders 48 of the wheels of the front axle in each 1-channel pressure regulation module 36, 38 of the front axle.

To form pneumatic circuit-separated pressure control channels (e.g. here: front axle pressure control channel or rear axle pressure control channel), each pressure control channel is therefore assigned its own compressed air reservoir 4, 6, with the pneumatic flow paths of each pressure control channel starting from the assigned compressed air reservoir 4, 6 via the assigned pressure control modules 16, 36, 38 up to the associated brake application devices 48, 50a, 50b are designed to be pneumatically separate from the pneumatic flow path of a respective other pressure control channel. The brake application devices 48 of the front axle are designed here as active pneumatic service brake cylinders 48 and the brake application devices 50a, 50b of the rear axle are designed as combined service and spring-loaded brake cylinders, with an active service brake part and a passive spring-loaded brake part.

A first drive wheel of the rear axle, which is preferably driven here, is braked by a first brake application device 50a and a second drive wheel of the rear axle is braked by a second brake application device 50b.

In order to form an electro-pneumatic brake system with primarily electrically actuated pressure control channels (front axle pressure control channel or rear axle pressure control channel) and a subordinate pneumatic fallback level in the event of an electrical failure, each pressure control module 16, 36, 38 is particularly preferably assigned its own back-up circuit , with its own back-up valve for the control of a pneumatic back-up or control pressure derived from the supply pressure of the respective pressure control circuit of the rear axle or the front axle assigned to the compressed air supply 4, 6 and formed by the foot brake value transmitter 2 which, in the event of a failure of electrical components, the respective brake pressure is formed at the working pressure connections of the pressure control modules 16, 36, 38.

The service braking device 1 of the towing vehicle and the braking device of the trailer are, as is usual with such braking systems, each coupled to one another by means of a coupling head "supply" 68 and each by means of a coupling head "brake" 70 . The supply pressure supplied by the towing vehicle is conducted in a trailer-side supply pressure line 72 shown in FIG. 2 and the control or braking pressure supplied by the towing vehicle is conducted in a trailer-side control pressure line 74 in the trailer. Since the trailer control module 64 does not have its own electronic control unit, the electrical brake control signals must be transmitted from the central brake control unit 14 via a CAN BUS "trailer" 78 and an electronic trailer interface 76 to the trailer if it has an electro-pneumatic brake system, but that is the case here is not the case. In the absence of an electro-pneumatic brake system on the trailer, there is no transmission of electrical brake control signals from the towing vehicle to the trailer. The trailer control module 64 as well as the 2-channel pressure control module 16 and the two 1-channel pressure control modules 36, 38 are each controlled by the central brake control unit 14 via an electrical control line 54, 88, 90, 92.

Against this background, the functioning of the braking device is as follows: During a normal braking process, the driver actuates the brake pedal and thus the foot brake value transmitter 2, which generates an electrical brake request signal in electrical channel 28 analogous to the desired setpoint deceleration and is fed into the central brake control unit 14 , which then controls the trailer control module 64, the 2-channel pressure control module 16 and the two 1-channel pressure control modules via the electrical control lines 54, 88, 90, 92 according to the brake request signal and possibly depending on other parameters such as the respective load. The respective integrated inlet solenoid valves, outlet solenoid valves and any back-up solenoid valves, which are usually designed as 2/2-way solenoid valves, are switched according to the braking requirement so that they pneumatically control the relay valves that are also integrated, to a target corresponding to the braking requirement - Brake pressure or target control pressure in the relevant brake application devices 48, 50a, 50b of the towing vehicle and to be controlled on the trailer side in the trailer control valve 80, which modulates the brake pressure for the brake cylinders 84 of the trailer from the setpoint control pressure. The pressure sensors integrated in the pressure control modules 16, 36 and 38 and in the trailer control module 64 then report the actual brake pressure or actual control pressure to the central brake control unit 14, which then regulates the setpoint brake pressure or setpoint control pressure by activating the solenoid valves on the module . In the central brake control unit 14 routines of a traction control (ASR), a brake slip control (ABS) and optionally also a vehicle dynamics control (ESP) and an adaptive cruise control (ACC) are implemented.

If the brake request signal for the central brake control unit 14 instead of the foot brake value sensor 2 from a driver assistance system such. B. the traction control (ASR), a vehicle dynamics control (ESP) or an adaptive cruise control (ACC) is generated, the same functions run as described above.

If the brake slip of one wheel or more wheels of the towing vehicle exceeds a predetermined brake slip limit of, for example, 12% to 14%, which can be determined via the wheel speed sensors 56, the brake slip control or the ABS of the towing vehicle responds. The brake pressures for the towing vehicle are set by the ABS routines implemented in the central brake control unit 14 by appropriate activation of the solenoid valves in the pressure control module 36, 38 assigned to the wheel that is slipping or in the pressure control module 16 assigned to the wheel that is slipping the brake slip control difference is corrected.

2 shows a schematic circuit diagram of the control system 300 of the towing vehicle of the towing vehicle-trailer combination. As part of the electronically regulated braking system (EBS) 1, the control system 300 comprises the central brake control unit 14 and an electronic drive control unit 93 of a drive device of the towing vehicle. The drive device here comprises, for example, a motor/gear unit 94 which drives a differential gear 96 via a central drive shaft 95 . From the differential gear 96 branch first and second drive shafts 97a, 97b, which then drive the first and second drive wheels 98a, 98b of the rear axle HA.

Furthermore, the control system 300 includes an electromechanical steering device 102, which is shown in detail in FIG. The electromechanical steering device 102 includes an electronic steering control unit 99, the function of which will be described later.

The steering control unit 99, the central brake control unit 14, the drive control unit 93 and an electronic control unit 100 of an autonomous vehicle control and/or a driver assistance system are connected to a vehicle data bus 101, for example, which is a CAN, for example. As a result, the steering control unit 99, the central brake control unit 14, the drive control unit 93 and the electronic control unit 100 can exchange data and control signals with one another. In particular, the central brake control unit 14 can control the drive control unit 93 in order, for example, to reduce the drive power of the motor 94 as part of the anti-slip regulation (TCS). The electronic control unit 100 can also control the central brake control unit 14 and/or the drive control unit 93 and/or the steering control unit 99 so that the towing vehicle is braked, steered and/or steered.

For steering braking, a steering brake function is implemented as a routine, for example in the central brake control unit 14, whereby the steered wheels 112a, 112b of the front axle VA and/or the drive wheels 98a, 98b of the rear axle HA can be braked in a targeted manner in order to achieve a desired steering effect on the towing vehicle achieve. This process is described further below.

The here, for example, electromechanical steering device 102 is shown in detail in FIG. 3 . The steering wheel torque 104 applied by the driver via the steering wheel 103 is introduced via a steering spindle 105 into an electric steering actuator 106, which is formed by an electric motor, for example. A steering wheel torque sensor 107 is also attached to the steering spindle 105, which detects the steering wheel torque 104 applied by the driver via the steering wheel 103 and feeds it as a steering wheel torque signal into the electronic steering control unit 99, which is connected to the vehicle data bus 101 (Fig. 2). The steering control unit 99 can basically control the steering actuator 106 as a function of the steering wheel torque 104 detected on the steering wheel 103 in order to generate an additional superimposed torque on the steering spindle 105 compared to the steering wheel torque 104 applied by the driver. Therefore, the steering device 102 represents here, for example, a so-called superimposed steering with steering torque superimposition. Instead of the steering wheel torque 104 or in addition to it, the respective steering wheel angle a can also be detected by a steering wheel angle sensor, so that superimposed steering with steering wheel angle superimposition would then be present.

However, the steering actuator 106 can also generate a steering torque 109 on the steering spindle 105 without the driver having to do anything, i.e. without actuating the steering wheel 103 . Also, the steering actuator 106 cannot feed a steering torque 109 into the steering spindle 105, so that the steering forces are derived solely from the steering wheel torque 104 generated by the driver. The steering request then comes exclusively from the driver, who actuates steering wheel 103 accordingly.

The steering spindle 105 opens into a steering gear 110, which here preferably has hydraulic power assistance, and increases the steering wheel torque 104 or the steering torque 109. The steering gear 110 then controls, via a steering linkage 110, steering knuckles 111a, 111b of the first and second front wheels 112a, 112b of the steered Front axle VA to set a steering angle ßi and ß2 for right and left there. The rear axle HA is preferably unsteered here.

For example, the steering torque 109 acting on the steering spindle 105 can be generated exclusively by the steering actuator 106 due to its activation by the electronic steering control unit 99, which, for example, receives a steering request from the electronic control 100 as part of an autonomous vehicle control and/or a driver assistance control, which is transmitted by the vehicle -Data bus 101 is transmitted as a steering request signal.

A situation is also conceivable in which a steering wheel torque 104 applied by the driver via the steering wheel 103 to the steering spindle 105 is superimposed on a steering torque 109 applied by the steering actuator 106 .

With the help of a so-called 98a on the rear axle HA and a first (then on the inside of the curve) steered wheel 112a on the front axle VA, a yaw moment Mbrake, yaw can be generated, which causes the towing vehicle to follow a left-hand curve here, for example. Decisive for the yawing moment M Brems, Yaer is the steering roll radius RLenkroii on the first steered front wheel 112a, which in combination with the braking force DF Brems, VA acting there generates a braking moment AFßrems.vA 'Lenkroii, furthermore half the axle length a, which in combination with the braking force AFß _re ms,HA at the first drive wheel 98a of the rear axle HA generates a braking torque AFß _re ms,HA ■ a. Overall, a yaw moment Mßrems, yaw due to steering braking is then effective:

Mßrems.Gier ⁼ AFßrems.VA ' RLenkroii + AFßrems.HA 'a

The steering brake function is implemented here, for example, in the central brake control unit 14, which then, by selectively activating the channels of the pressure control modules 36, 38 and 16, individually brakes the first drive wheel 98a, for example, by applying the associated brake application device 50a and the first steered front wheel 112a causes the associated brake application device 48 to be applied. The steering brake request for the steering braking is generated here, for example, by the electronic controller 100 and transmitted to the central brake control unit 14 via the vehicle data bus 101 .

The anti-slip regulation (ASR) is automatically activated, for example, when impermissible wheel slip has been detected on the first drive wheel and/or on the second drive wheel of the rear axle HA. The impermissible drive slip is determined on the basis of the signals from the speed sensors 56 on the first drive wheel 98a and/or on the second drive wheel 98b by the central brake control unit 14 on the basis of the wheel speed signals which the speed sensors 56 deliver and report to the central brake control unit 14. In principle, the central brake control unit 14 can then control the 2-channel pressure control module 16 in order to activate the service brake part of the first brake application device 50a of the rear axle HA and/or the service brake part of the second brake application device 50b of the rear axle in order to activate the first drive wheel 98a and/or the second Brake drive wheel 98b of the rear axle HA, so that there may be an impermissible Drive slip is returned to a permissible drive slip. Additionally or alternatively, as already explained above, the central brake control unit 14 can also control the drive control unit 93 for this purpose in order to reduce the drive power of the engine 94 as part of the traction control system (ASR), which in turn results in less traction slip of the two drive wheels 98a, 98b results.

Fig. 4 now shows a flow chart of a preferred embodiment of a method for operating the control system 300.

After the start of the method, a query is made in a first, optional step 310 as to whether the steering device 102 has an error or defect. The error can be detected by self-monitoring or by external monitoring of the steering device 102 .

If this is not the case ("no"), a steering request signal can be generated by the steering device 102 itself, i.e. by the steering wheel 103 controlled by the driver and/or by the electronic steering control unit 99, whereupon the steering effect corresponding to the steering request signal is carried out.

However, if this is the case ("yes"), a steering request signal can be generated or implemented by the steering device 102 itself, i.e. neither by the steering wheel 103 controlled by the driver nor by the electronic steering control unit 99.

In a subsequent step 320, a query is then made as to whether a steering request signal is present, which has been generated, for example, by electronic control unit 100, in particular by the autonomous vehicle control implemented there and/or by a driver assistance system implemented there. Electronic control unit 100 can be designed such that it generates a steering request signal as redundancy for steering device 102 when an error or a detected defect is detected in steering device 102 by the autonomous vehicle control implemented there and/or the driver assistance system implemented there.

If this is not the case (“no”), ie there is no steering request signal, electronic control unit 100 does not request steering of the towing vehicle. However, if this is the case (“yes”), ie if the electronic control unit 100 has generated a steering request signal, which can be obtained by querying the data bus on the vehicle 101 signals is possible, then the steering request signal is implemented in a step 330 by the steering brake function implemented in the central brake control unit 14 (“steering by steering brakes”).

In a subsequent step 340, a query is then made as to whether the traction control system (TCS) on the driven rear axle HA is active or has been activated. This query preferably takes place within the central brake control unit 14, in which the anti-slip regulation (ASR) is implemented. The traction control system (TCS) on the rear axle HA is activated if it has been determined that at least one of the drive wheels 98a, 98b is impermissibly driving slip.

If this is not the case ("no"), the steering by steering brakes in step 330 as described above and thus the desired steering effect (continue) to be carried out until the desired steering effect has occurred, which can be realized by steering angle control. However, if this is the case ("yes"), traction control (ASR) is carried out in a subsequent step 350, but activation of braking device 1, ie targeted braking of drive wheels 98a, 98b of rear axle HA, is dispensed with and, for example, only the drive control device 93 is actuated in order to reduce the drive power of the motor 94 in order thereby to reduce the drive slip on the drive wheels 98a, 98b alone. This measure is intended to avoid braking forces initiated by the ASR control and generated by the braking device 1, which could have a negative effect on the steering braking. In other words, the ASR control is limited to reducing the drive power and there is no braking intervention.

service braking device

foot brake sensor

VA storage pressure tank

HA reservoir pressure tank

air treatment module

supply line

supply line

brake control unit

2-channel pressure control module

VA foot brake valve

supply line

supply line

control line

RA foot brake valve electric channel

brake data bus

control line

1-channel pressure control module

1-channel pressure control module

brake line

brake line

Trailer pressure tank

supply line

Brake application device VA a first brake application device HA b second brake application device RA control line electric control line speed sensors electric signal lines wear sensors electric signal lines trailer control module parking brake unit coupling head "supply" coupling head "brake" reservoir pressure line control pressure line trailer interface trailer data bus trailer control valve non-return valve electric control line electric control line electric control line drive control unit engine/gearbox unit drive shaft differential gear a first drive shaft b second driveshaft 98a first drive wheel

98b second drive wheel

99 Steering Controller

100 electronic control unit

101 vehicle data bus

102 steering device

103 steering wheel

104 steering wheel torque

105 steering spindle

106 steering actuator

107 steering wheel torque sensor

109 steering torque

110 steering gear

111a first knuckle

111b second knuckle

112a first front wheel

112b second front wheel

300 control system

Claims

PATENT CLAIMS

1. A method for operating a control system (300) of a vehicle, which has at least the following: a) a drive motor (94) controlled by a drive controller (93), which has at least one driven axle (HA) with a first drive wheel (98a) and a second drive wheel (98b), b) a differential gear (96) between the first drive wheel (98a) and the second drive wheel (98b), which is driven by the drive motor (94), c) a brake device controlled by a brake controller (14). (1) with a first brake actuator (50a) for the first drive wheel (98a) and a second brake actuator (50b) for the second drive wheel (98b), d) a steering brake function with which the first brake actuator (50a) and/or or the second brake actuator (50b) of the at least one driven axle (HA), a steering effect on the vehicle can be achieved, e) traction control (ASR), with which an impermissible traction slip upf on the first drive wheel (98a) and/or on the second drive wheel (98b) of the at least one driven axle (HA) by e1) an intervention in the drive control (93) of the drive motor (94), in which the drive power of the drive motor ( 94) is reduced, and/or by e2) an intervention in the brake control (14) of the braking device (1), in which an inadmissibly slipping drive wheel is braked in a targeted manner by the first drive wheel (98a) and/or by the second drive wheel (98b). is, can be traced back to a permissible drive slip, wherein f) if the steering brake function on the at least one driven axle (HA) is active or has been activated, and if then and the drive slip control (ASR) on the at least one driven axle (HA) is activated is, within the framework of the traction control (ASR) on the intervention in the brake control (14) of the braking device (1) is dispensed with.

2. The method according to claim 1, characterized in that the intervention in the drive control (93) of the drive motor (94) is carried out.

3. The method according to claim 1 or 2, characterized in that as part of the traction control system (ASR), the intervention in the brake control (14) of the braking device (1) is only dispensed with if the driving speed (v) of the vehicle is less than a predetermined one Limit speed (v _limit ) is.

4. The method according to any one of the preceding claims, characterized in that the control system (300) further a) a steering device (102), and / or b) an autonomous vehicle control (100), and / or c) at least one driver assistance system (100) includes, by which and / or by which a steering request signal can be generated, with which cornering of the vehicle is brought about.

5. The method according to claim 4, characterized in that the steering request signal of the autonomous vehicle control and/or the driver assistance system is used to steer the vehicle if it has been determined that the steering device (102) has an error or defect and is then unable to generate a steering request signal .

6. The method according to claim 5, characterized in that the steering request signal is implemented by means of steering brakes at least on the driven axle (HA).

7. The method according to claim 6, characterized in that during steering braking of the first drive wheel (98a) and the second drive wheel (98b) of the drive axle (HA) that drive wheel (98a) is braked which is represented in relation to the cornering by the steering request signal of the vehicle represents the drive wheel on the inside of the curve. Method according to Claim 7, characterized in that during steering braking the drive wheel (98b) on the outside of the curve, which deviates from the drive wheel (98a) on the inside of the curve, is not braked. Method according to one of the preceding claims, characterized in that the braking device is an electro-pneumatic and electronically controlled braking system (1) with a 2-channel pressure control module (16) and / or with two 1-channel pressure control modules, a first 1-channel - Pressure control module and a second pressure control module on which at least one driven axle (HA) is used, a first brake pressure for the first brake actuator (50a ) and a second brake pressure for the second brake actuator (50b) can be individually regulated by a second channel of the 2-channel pressure control module (16) or of the second 1-channel pressure control module. Method according to one of the preceding claims, characterized in that the traction control system (ASR) is activated automatically if impermissible traction slip is detected on the first drive wheel (98a) and/or on the second drive wheel (98b) of the at least one driven axle (HA). has been. Vehicle, in particular towing vehicle of a towing vehicle-trailer combination with a control system (300) which is controlled by a method according to one of the preceding claims.